Legal claims defining the scope of protection. Each claim is shown in both the original legal language and a plain English translation.
1. A service data transmission method, comprising: obtaining first information from a service server, wherein the first information comprises at least one of service information or application information; obtaining second information from user equipment, wherein the second information comprises at least one of the service information, mobility information, behavior information, or status information of the user equipment; and controlling transmission of service data of the user equipment based on the first information, obtained from the service server, and the second information obtained from the user equipment.
This invention relates to a method for optimizing service data transmission in a networked system, addressing inefficiencies in data delivery between user equipment (UE) and service servers. The method dynamically adjusts data transmission based on real-time conditions to improve performance, reliability, and resource utilization. The method involves collecting two types of information: first, service-related data from a service server, which may include details about the service itself or application-specific parameters. Second, it gathers data directly from the user equipment, such as service usage patterns, mobility status (e.g., location or movement), user behavior metrics, or device status (e.g., battery level or network connectivity). By analyzing both sets of information, the system determines the optimal way to transmit service data to or from the user equipment. This could involve prioritizing certain data types, adjusting transmission rates, or selecting the most efficient network path based on current conditions. The goal is to enhance data delivery efficiency while minimizing latency, bandwidth consumption, and power usage. The method is particularly useful in scenarios where network conditions or user behavior are highly variable, such as in mobile or IoT environments.
2. The method according to claim 1 , wherein at least part of the first information is obtained by the service server from the user equipment.
Technical Summary: This invention relates to a method for managing information in a networked system involving a service server and user equipment. The problem addressed is the efficient and secure retrieval, processing, and utilization of information between these components to enhance service delivery or user experience. The method involves obtaining first information, which may include user data, device data, or service-related data, from the user equipment by the service server. This information is then processed to support various functions such as authentication, service personalization, or system optimization. The method ensures that the information is securely transmitted and handled, potentially involving encryption or access controls to protect sensitive data. Additionally, the method may involve obtaining second information from a different source, such as another server or database, to supplement or verify the first information. This second information can be used to cross-reference, validate, or enrich the data obtained from the user equipment, improving the accuracy and reliability of the system's operations. The method may also include steps to process the combined information to generate outputs such as personalized recommendations, service adjustments, or security measures. The system ensures that the information flow is efficient, minimizing latency and resource usage while maintaining data integrity and security. This approach is particularly useful in applications where real-time data exchange between user devices and servers is critical, such as in cloud computing, IoT systems, or mobile services. The method enhances the functionality and security of such systems by optimizing information handling and processing.
3. The method according to claim 1 , wherein the service information comprises at least one of service flow information, a service volume, a service scheduling level indication, and service status information of a service flow in which the service data is located; and the service flow information comprises at least one of: a service flow identifier, a service flow class, a mobility requirement of the service flow, a delay requirement of the service flow, transport layer information of the service flow, routing information of the service flow, and server information of the service flow.
This invention relates to service information management in communication networks, specifically addressing the need for detailed service flow metadata to optimize data transmission. The method involves collecting and utilizing comprehensive service information to enhance network performance. This information includes service flow details such as identifiers, classes, mobility and delay requirements, transport layer data, routing paths, and server details. Additionally, it captures service volume metrics, scheduling priorities, and status updates for ongoing service flows. By integrating these parameters, the system enables more efficient routing, resource allocation, and quality-of-service (QoS) management. The solution ensures that network operations adapt dynamically to varying service demands, improving reliability and reducing latency. This approach is particularly valuable in environments where real-time data transmission and precise service differentiation are critical, such as in 5G networks or IoT applications. The detailed service information allows for granular control over data flows, supporting advanced features like traffic prioritization and adaptive routing based on specific service characteristics.
4. The method according to claim 1 , wherein the mobility information comprises at least one of: a moving rate, a moving direction, current location information, predicted location information, signal quality information, and a handover preparation indication.
This invention relates to wireless communication systems, specifically methods for managing mobility information to improve network performance and user experience. The problem addressed is the need for efficient and accurate mobility tracking to support seamless connectivity, especially in dynamic environments where devices move frequently. The method involves collecting and utilizing mobility information to optimize network operations. This mobility information includes various data points such as the moving rate (speed) of a device, its moving direction, current location data, predicted future location data, signal quality metrics, and indicators of handover preparation (preparing to switch between network nodes). By gathering and analyzing these parameters, the system can anticipate device movements, predict signal degradation, and proactively initiate handover procedures to maintain stable connections. This reduces latency, minimizes service interruptions, and enhances overall network efficiency. The approach is particularly useful in scenarios like vehicular communications, mobile broadband, and IoT applications where devices frequently change locations or experience varying signal conditions. The method ensures that mobility data is leveraged effectively to support real-time decision-making in wireless networks.
5. The method according to claim 1 , wherein the behavior information comprises information that is entered by a user into the user equipment, and the entered information is used to control any of a working status of software, an operating system, or a bottom-layer module in the user equipment.
This invention relates to user equipment (UE) systems where behavior information entered by a user directly influences the operation of software, the operating system, or low-level hardware modules. The system captures user inputs, such as commands or preferences, and translates them into control signals that modify the operational state of the UE. This allows users to dynamically adjust system behavior, such as enabling or disabling software features, altering system settings, or optimizing hardware performance based on real-time user interactions. The invention ensures that user-provided data is processed and applied to control critical system components, enhancing customization and responsiveness. The approach may involve parsing user inputs, validating them, and executing corresponding system-level adjustments without requiring intermediate software layers. This method improves user control over device functionality while maintaining system stability and security. The solution is particularly useful in environments where users need fine-grained control over device operations, such as in industrial, medical, or high-performance computing applications. The invention ensures that user inputs are accurately interpreted and applied to the appropriate system components, enabling precise and immediate adjustments to device behavior.
6. The method according to claim 1 , wherein the status information comprises at least one of: a quantity of electricity, a screen resolution, a screen size, sensor information, a type of an operating system, and central processing unit usage.
This invention relates to a method for collecting and utilizing device status information in a computing system. The method addresses the challenge of efficiently gathering and processing diverse types of device data to optimize system performance, user experience, or application functionality. The status information includes at least one of the following: the quantity of electricity (e.g., battery level), screen resolution, screen size, sensor data (e.g., accelerometer, gyroscope), the type of operating system, and central processing unit (CPU) usage. This data is collected to enable adaptive adjustments, such as power management, display optimization, or system resource allocation. The method ensures compatibility across different devices by accounting for variations in hardware and software configurations. By monitoring these parameters, the system can dynamically respond to changes in device state, improving efficiency and user interaction. The invention is particularly useful in mobile devices, embedded systems, or any environment where real-time status awareness is critical for performance optimization.
7. The method according to claim 1 , wherein the controlling the transmission of the service data comprises: performing, based on at least one of the first information or the second information, at least one of the following operations: (a) establishing a plurality of bearers or a plurality of flows for the service data; (b) determining a scheduling priority of the service data; (c) determining a transmission delay of the service data; (d) determining a bit rate of the service data; (e) establishing a transport layer proxy for the service data on a network side; (f) selecting a service server for a service corresponding to the service data; (g) determining a decoding manner of the service data; (h) determining whether the service data can be transmitted by occupying a resource on the network side; (i) determining a type of a resource used for data transmission of the service data; and (j) performing a local exchange for the service corresponding to the service data.
This invention relates to optimizing the transmission of service data in a network, particularly for improving efficiency, reliability, and performance in data communication systems. The method involves controlling the transmission of service data based on first information (e.g., network conditions, device capabilities) and second information (e.g., service requirements, user preferences). The control operations include establishing multiple bearers or flows for the service data to enhance throughput and reliability. It also determines scheduling priorities, transmission delays, and bit rates to ensure timely and efficient data delivery. A transport layer proxy may be set up on the network side to manage data flow, and an appropriate service server is selected for the service. The method further determines the decoding manner of the service data, whether network resources can be occupied for transmission, and the type of resources used. Additionally, it supports local exchange for the service, allowing data to be processed or relayed locally rather than transmitted over the network. These operations collectively enhance network performance, reduce latency, and improve resource utilization.
8. The method according to claim 1 , wherein the controlling the transmission of the service data comprises: sending third information to the service server or the user equipment, wherein the third information is used to control transmission of the service data of the user equipment, wherein the third information comprises at least one of: load information of a cell, cell edge indication information, handover indication information, transport layer proxy information of the cell, information about available bandwidth of the user equipment, and bit rate switching indication information.
This invention relates to wireless communication systems, specifically methods for controlling the transmission of service data between user equipment (UE) and a service server. The problem addressed is optimizing data transmission efficiency and quality of service (QoS) in cellular networks by dynamically adjusting transmission parameters based on network and device conditions. The method involves monitoring various network and device metrics to generate control information, which is then sent to either the service server or the UE to regulate data transmission. The control information includes load information of the cell, indicating the current traffic conditions; cell edge indication information, signaling whether the UE is near the cell boundary; handover indication information, alerting when a handover is imminent; transport layer proxy information, detailing proxy settings for the cell; available bandwidth of the UE, reflecting its current data capacity; and bit rate switching indication information, suggesting adjustments to the data transmission rate. By providing this detailed control information, the system can dynamically adapt transmission parameters to improve efficiency, reduce latency, and enhance QoS, particularly in scenarios with varying network conditions or device capabilities. The approach ensures that data transmission is optimized based on real-time conditions, benefiting both the network operator and the end user.
9. The method according to claim 1 , wherein the service data transmission method is implemented via an information control center.
This invention relates to a service data transmission method for managing and transmitting data in a networked system, particularly in environments where centralized control is required. The method addresses the challenge of efficiently routing and processing service data between multiple devices or nodes while ensuring reliability, security, and real-time performance. The core of the invention involves using an information control center to oversee the transmission of service data. This control center acts as a central hub, coordinating data flow between different endpoints, such as sensors, actuators, or other networked devices. The control center may perform functions like data aggregation, filtering, encryption, and prioritization to optimize transmission efficiency and security. The method ensures that service data is transmitted in a structured manner, reducing latency and minimizing errors. The control center may also monitor network conditions, dynamically adjusting transmission parameters to maintain optimal performance. Additionally, the system may support bidirectional communication, allowing for both data collection and command issuance from the control center to connected devices. This approach is particularly useful in industrial automation, smart infrastructure, or IoT applications where centralized management of data transmission is critical. By centralizing control, the method improves scalability, security, and reliability compared to decentralized or peer-to-peer transmission models. The invention ensures that service data is transmitted securely and efficiently, even in complex or high-demand environments.
10. The method according to claim 9 , wherein the information control center transmits third information, generated based on the first and second information, to the user equipment, and software of the user equipment controls data transmission based on the third information.
This invention relates to a system for managing data transmission between user equipment and an information control center. The system addresses the challenge of efficiently controlling data flow in communication networks, particularly where multiple devices interact with a central control point. The method involves collecting first information from user equipment, such as device status or network conditions, and second information from the information control center, such as network policies or user preferences. The control center processes this data to generate third information, which includes instructions or parameters for optimizing data transmission. This third information is then sent back to the user equipment, where software on the device uses it to regulate data transfer operations. The system ensures that data transmission adheres to predefined rules, network constraints, or user requirements, improving efficiency and reliability. The method may also involve dynamically adjusting transmission parameters based on real-time conditions, ensuring adaptive and responsive data management. This approach is particularly useful in scenarios where centralized control of distributed devices is necessary, such as in IoT networks or cloud-based systems.
11. A service data transmission apparatus, comprising: a receiver, configured to: receive first information from a service server, wherein the first information comprises at least one of service information or application information; and receive second information from user equipment, wherein the second information comprises at least one of the service information, mobility information, behavior information, or status information of the user equipment; and a processor, operatively coupled to the receiver, and configured to: control transmission of service data of the user equipment based on the first information, received from the service server, and the second information received from the user equipment.
The service data transmission apparatus operates in the domain of network communication systems, addressing the challenge of efficiently managing and transmitting service data between user equipment (UE) and service servers. The apparatus includes a receiver and a processor. The receiver collects two types of information: first information from a service server, which includes service or application details, and second information from the UE, which may include service-related data, mobility status, user behavior, or device status. The processor uses this combined information to dynamically control the transmission of service data between the UE and the service server. This ensures optimized data delivery based on real-time conditions, such as the UE's mobility or behavior, and the service requirements. The system enhances data transmission efficiency by leveraging both server-side and client-side data to make informed decisions on how to route or prioritize service data. This approach improves network performance and user experience by adapting to changing conditions without manual intervention.
12. The apparatus according to claim 11 , wherein the service information comprises at least one of service flow information, a service volume, a service scheduling level indication, and service status information of a service flow in which the service data is located, and the service flow information comprises at least one of: a service flow identifier, a service flow class, a mobility requirement of the service flow, a delay requirement of the service flow, transport layer information of the service flow, routing information of the service flow, and server information of the service flow.
This invention relates to apparatuses for managing service data in communication networks, particularly focusing on enhancing service flow handling. The problem addressed is the lack of detailed service information in existing systems, which can lead to inefficient resource allocation, suboptimal service delivery, and poor quality of service (QoS) management. The apparatus includes a processing unit configured to obtain service information associated with service data. This service information includes various attributes such as service flow information, service volume, scheduling level indication, and service status. The service flow information further comprises identifiers, class, mobility requirements, delay requirements, transport layer details, routing information, and server details. These attributes enable precise characterization of service flows, allowing the apparatus to optimize data transmission, resource allocation, and QoS management. By incorporating comprehensive service information, the apparatus ensures that service flows are handled according to their specific requirements, improving efficiency and reliability in communication networks. This is particularly useful in scenarios where different services have varying demands, such as real-time applications requiring low latency or high-bandwidth services needing prioritized routing. The detailed service information allows the apparatus to dynamically adjust to these demands, enhancing overall network performance.
13. The apparatus according to claim 11 , wherein the mobility information comprises at least one of: a moving rate, a moving direction, current location information, signal quality information, predicted location information, and a handover preparation indication.
This invention relates to wireless communication systems, specifically to apparatuses that enhance mobility management for user devices. The problem addressed is the need for more efficient and accurate tracking of device mobility to improve handover decisions, reduce connection disruptions, and optimize network resource allocation. The apparatus includes components for collecting and processing mobility information about a user device. This mobility information includes various data points such as the device's moving rate, moving direction, current location, signal quality, predicted future location, and handover preparation status. By analyzing these factors, the apparatus can make more informed decisions about when and how to initiate handovers between network cells, ensuring seamless connectivity as the device moves. The system may also use this data to anticipate future mobility patterns, allowing for proactive adjustments to network configurations. This approach reduces latency, minimizes service interruptions, and improves overall network efficiency by aligning resource allocation with actual device movement. The invention is particularly useful in high-mobility environments like urban areas or transportation networks, where rapid and accurate mobility tracking is critical.
14. The apparatus according to claim 11 , wherein the status information comprises at least one of: a quantity of electricity, a screen resolution, a screen size, sensor information, a type of an operating system, and central processing unit usage.
This invention relates to an apparatus for monitoring and reporting device status information in a computing system. The apparatus is designed to address the challenge of efficiently collecting and transmitting detailed status data from a device to a remote server or another computing entity. The apparatus includes a data collection module that gathers status information from various components of the device, such as hardware and software elements. This status information may include metrics like the quantity of electricity (e.g., battery level), screen resolution, screen size, sensor data (e.g., accelerometer, gyroscope), the type of operating system running on the device, and central processing unit (CPU) usage. The collected data is then processed and transmitted to a remote server or another computing entity for analysis, diagnostics, or further processing. The apparatus ensures that the status information is accurately captured and relayed, enabling better device management, performance optimization, and troubleshooting. The invention is particularly useful in scenarios where real-time or periodic monitoring of device health and performance is required, such as in IoT devices, mobile computing, or enterprise systems.
15. The apparatus according to claim 11 , wherein the processor is configured to perform, based on at least one of the first information or the second information, at least one of the following operations: (a) establishing a plurality of bearers or a plurality of flows for the service data; (b) determining a scheduling priority of the service data; (c) determining a transmission delay of the service data; (d) determining a bit rate of the service data; (e) establishing a transport layer proxy for the service data on a network side; (f) selecting a service server for a service corresponding to the service data; (g) determining a decoding manner of the service data; (h) determining whether the service data can be transmitted by occupying a resource on the network side; (i) determining a type of a resource used for data transmission of the service data; and (j) performing a local exchange for the service corresponding to the service data.
This invention relates to network communication systems, specifically improving the handling of service data in wireless or wired networks. The problem addressed is the inefficient management of service data, leading to suboptimal resource allocation, transmission delays, and poor quality of service (QoS). The invention provides an apparatus with a processor that dynamically processes service data based on first and second information, which may include service characteristics, network conditions, or user preferences. The processor performs various operations to optimize data transmission. It can establish multiple bearers or flows for the service data to ensure efficient routing. It determines scheduling priorities, transmission delays, and bit rates to balance network load and meet service requirements. The processor may also set up a transport layer proxy on the network side to manage data flow efficiently. It selects appropriate service servers for the data and determines the decoding method to ensure compatibility and performance. The processor assesses whether the data can be transmitted without overloading network resources and identifies the type of resources needed for transmission. Additionally, it supports local exchange for services, allowing data to be processed closer to the user, reducing latency and improving efficiency. These features collectively enhance network performance and user experience.
16. The apparatus according to claim 11 , further comprising: a transmitter, operatively coupled to the processor, and configured to send third information to the service server or the user equipment, wherein the third information is used to control transmission of the service data of the user equipment, and the third information comprises at least one of: load information of a cell, cell edge indication information, handover indication information, transport layer proxy information of the cell, information about available bandwidth of the user equipment, and bit rate switching indication information.
This invention relates to wireless communication systems, specifically improving service data transmission control between user equipment (UE) and a service server. The problem addressed is inefficient data transmission due to lack of real-time network and device conditions, leading to suboptimal performance. The apparatus includes a processor that generates control information based on network and UE status, and a transmitter that sends this information to either the service server or the UE. The control information includes load status of a cell, indicators for cell edge or handover events, transport layer proxy details, available bandwidth of the UE, and bit rate adjustment signals. This allows dynamic adaptation of data transmission parameters to optimize performance based on current conditions. The system ensures efficient use of network resources by adjusting transmission rates, routing decisions, and proxy configurations in response to real-time feedback. The solution enhances data throughput and reliability by leveraging detailed network and device metrics.
17. A non-transitory machine-readable medium having stored therein a computer program having at least one code section for distributing data, the at least one code section being executable by one or more processors and, when executed, causes the one or more processors to provide execution comprising: obtaining first information from a service server, wherein the first information comprises at least one of service information or application information; obtaining second information from user equipment, wherein the second information comprises at least one of the service information, mobility information, behavior information, and status information of the user equipment; and controlling transmission of service data of the user equipment based on the first information, obtained from the service server, and the second information obtained from the user equipment.
This invention relates to a data distribution system for optimizing service delivery in a network environment. The system addresses the challenge of efficiently managing and transmitting service data to user equipment (UE) by leveraging both server-side and client-side information. The solution involves a computer program stored on a non-transitory machine-readable medium, which, when executed by one or more processors, performs a series of steps to enhance data transmission control. The system obtains first information from a service server, which includes service-related data or application-specific details. Additionally, it retrieves second information directly from the user equipment, encompassing service data, mobility patterns, user behavior, and device status. By analyzing both sets of information, the system dynamically adjusts the transmission of service data to the user equipment. This approach ensures that data delivery is optimized based on real-time conditions, improving efficiency and performance. The integration of server and client data allows for adaptive and context-aware service distribution, addressing limitations in traditional static data transmission methods. The invention is particularly useful in scenarios requiring dynamic resource allocation and personalized service delivery.
18. The non-transitory machine-readable medium according to claim 17 , wherein the service information comprises at least one of service flow information, a service volume, a service scheduling level indication, and service status information of a service flow in which the service data is located; and the service flow information comprises at least one of: a service flow identifier, a service flow class, a mobility requirement of the service flow, a delay requirement of the service flow, transport layer information of the service flow, routing information of the service flow, and server information of the service flow.
This invention relates to a non-transitory machine-readable medium storing instructions for managing service data in a networked system. The technology addresses the challenge of efficiently handling service data by providing detailed service information to optimize data processing, routing, and scheduling. The service information includes service flow details, such as identifiers, classes, mobility and delay requirements, transport layer data, routing paths, and server details. It also encompasses service volume metrics, scheduling priority levels, and status updates for ongoing service flows. This structured approach ensures that service data is processed according to its specific requirements, improving network performance and resource allocation. The solution enhances data management by associating service data with comprehensive metadata, enabling systems to prioritize, route, and monitor flows dynamically. The invention is particularly useful in environments where real-time data handling and adaptive scheduling are critical, such as in cloud computing, telecommunications, or edge computing networks. By integrating these service attributes, the system can make informed decisions to meet performance targets while maintaining efficiency.
19. The non-transitory machine-readable medium according to claim 17 , wherein the mobility information comprises at least one of: a moving rate, a moving direction, current location information, predicted location information, signal quality information, and a handover preparation indication.
This invention relates to wireless communication systems, specifically to methods for managing mobility in wireless networks. The problem addressed is the need for efficient and accurate mobility management to ensure seamless connectivity as mobile devices move between different network coverage areas. The invention provides a non-transitory machine-readable medium containing instructions for processing mobility information to optimize network performance and user experience. The mobility information includes various parameters such as the moving rate, moving direction, current location, predicted location, signal quality, and handover preparation indication. These parameters help the network predict device movement patterns, anticipate coverage changes, and prepare for handover procedures. By analyzing this information, the system can make informed decisions to maintain stable connections, reduce latency, and minimize service interruptions during transitions between network nodes or cells. The solution enhances network efficiency by proactively managing resources and ensuring smooth handover processes, particularly in dynamic environments where device mobility is frequent. This approach improves overall network reliability and user satisfaction by minimizing disruptions during mobility events.
20. The non-transitory machine-readable medium according to claim 17 , wherein the at least one code section, when executed, further causes the one or more processors to provide execution comprising: performing, based on at least one of the first information or the second information, at least one of the following operations: (a) establishing a plurality of bearers or a plurality of flows for the service data; (b) determining a scheduling priority of the service data; (c) determining a transmission delay of the service data; (d) determining a bit rate of the service data; (e) establishing a transport layer proxy for the service data on a network side; (f) selecting a service server for a service corresponding to the service data; (g) determining a decoding manner of the service data; (h) determining whether the service data can be transmitted by occupying a resource on the network side; (i) determining a type of a resource used for data transmission of the service data; and (j) performing a local exchange for the service corresponding to the service data.
This invention relates to network communication systems, specifically methods for optimizing service data transmission in wireless or wired networks. The problem addressed is the inefficient handling of service data, leading to suboptimal resource utilization, delays, and poor quality of service. The solution involves a machine-readable medium with executable code that enhances service data processing by performing various operations based on first and second information (e.g., service requirements, network conditions, or device capabilities). The system establishes multiple bearers or flows for service data to improve transmission efficiency. It determines scheduling priorities, transmission delays, and bit rates to optimize performance. A transport layer proxy can be set up on the network side to manage data flow. The system also selects appropriate service servers and determines decoding methods for the data. Additionally, it assesses whether service data can be transmitted by occupying network resources and identifies the type of resources needed. Local exchange mechanisms are implemented to further enhance service delivery. These operations collectively improve data handling, reduce latency, and ensure better resource allocation in network communications.
Unknown
September 8, 2020
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